Piston-Pin Bore Dimensions for a Piston of an Internal Combustion Engine

ABSTRACT

A coating for a tribologically heavily loaded component, wherein the coating is in the form of a ceramic coating made of an organic-inorganic prepolymer which is pyrolyzed after being applied to the component.

BACKGROUND

The surfaces in the combustion chamber of an internal combustion engine over which hot combustion gases pass tend fundamentally to oxidation. Especially affected thereby are the crowns of the pistons of the internal combustion engine. Regardless of the type of piston construction, this oxidation occurs with steel and light-weight pistons. Because of the resulting hot gas corrosion and the resulting thermo-mechanical stress on the areas of the piston crown, in particular, the edge areas if the piston has a combustion bowl, fractures occur in the area of the piston crown.

Steps have already been taken to counter this, which so far have all been unsatisfactory. A temperature-stable, high-temperature paint on the basis of polyphosphates, chromates and aluminum powder is known from DE 196 29 399 A1 but which, because of environmental regulations, is difficult to handle in a production process. A multi-layer coat of different materials consisting of undercoat, middle coat and topcoat is known from DE 40 03 038 CT which is laborious to apply in the production of a piston. Plasma-sprayed coats are known from DE 198 52 285 C2 which are also time-consuming in production. From DE 198 52 285 C2 it is known to conform the coefficients of thermal expansion of glass, metal and ceramics by a suitable process, wherein no reference is made to internal combustion engines.

SUMMARY

A coating for a tribologically heavily loaded component is disclosed which creates a high-temperature resistant corrosion protection layer for the component. The coating is a ceramic coating made of an organic prepolymer which is pyrolyzed after being applied to the component.

DETAILED DESCRIPTION

A coating for a tribologically heavily loaded component is disclosed, the result of which is a high-temperature resistant corrosion protection layer for the component.

The coating is a ceramic coating made of an organic prepolymer which is pyrolyzed after being applied to the component.

The metals can be from the group Si (silicon), Ti (titanium), Zr (zirconium), Al (aluminum), Sn (tin) or Ce (cerium), for example. These metals are converted completely or partially into oxides in the course of pyrolysis at temperatures found particularly in the combustion chamber between 200° C. and 450° C. and sintered to each other so the high-temperature resistant protective layer against hot gas corrosion is created.

A thin coating of the organic-inorganic prepolymer is applied to the component which then undergoes pyrolysis. The coating is on the one hand very thin, and on the other hand the pyrolysis process does not have to be performed during production of the component but can be carried out after installation of the component and the start of operation. When using the coating on a piston for an internal combustion engine, the coating can be applied at the piston manufacturer while the actual pyrolysis does not take place until the piston is installed in the internal combustion engine and the engine has started operation. After the initial combustion events, the coating is pyrolized and offers a high-temperature resistant protection layer for the piston crown from hot gas corrosion in the combustion chamber of the internal combustion engine so that the service life of the piston is substantially increased.

In a method of applying the coating, it must be remembered that the entire piston crown, regardless of whether it has a combustion bowl or not, is given the coating. If the piston has a combustion bowl, consideration can be given to coating only the combustion bowl completely or even only the edge areas of the combustion bowl in order to protect the area stressed by the hot gas corrosion effectively.

In the oxidic matrix, the oxidation-resistant metallic particles admixed into the precursors can consist of Al, Cu, Fe, Cr, Ni or Co, where here the list is not complete. In addition, an alloy of the metallic particles named can be used which serve to conform the coefficients of thermal expansion and act as fillers to prevent shrinkage cracks during pyrolysis. By admixing the materials named, on the one hand the coefficient of thermal expansion of the coating is conformed to the material of the component and on the other hand material stresses, in particular shrinkage cracks, are effectively prevented.

In a further aspect, paint pigments are admixed to the coating. It is self-evident that the admixed paint pigments are also heat-resistant. For example, black or other dark pigments can be used to increase radiation absorption, resulting in improved heat dissipation.

In a further aspect, metallic pigments are admixed to the coating. Such metallic pigments serve to increase the degree of reflection, and thereby effectively prevent hot gas corrosion through the reduction in component temperature. In addition, the coefficients of thermal expansion of the component and the coating can be conformed to each other through the metallic pigments so that thermal stresses between the coating and the component are reduced.

In a further aspect, ceramic fillers particles) are admixed to the coating. These ceramic fillers (in particular, nanoparticles) increase the lubricity of the coating so that not only is hot-gas corrosion prevented but the friction of the coating is lowered.

In a further aspect, several of the aforementioned types of pigment can be combined with each other.

A simple and cost-effective production process consists of applying the coating to the component, for example, by spraying, immersion, application by doctor blade or similar. Then the component is dried, wherein either after drying, the component undergoes heat treatment whereby the coating is pyrolyzed. However, this can be omitted at the manufacturer of the component, in particular of the piston, if the component is being delivered to the one who installs it and then undergoes heat treatment in its operating condition. Thus, it is normally the case that a supplier to an automobile maker produces pistons, gives them the disclosed coating which is initially only dried. When the piston is delivered to the automobile maker, or the manufacturer of the internal combustion engine, it can be installed whereupon the pyrolysis of the coating takes place the first time the internal combustion engine is started. No additional steps for pyrolysis are then necessary so that the high-temperature resistant corrosion protection layer is available immediately when the internal combustion engine commences operation. 

1. A piston with a piston boss in which a piston-pin bore is located to accommodate a piston pin, wherein the piston-pin bore is continuously widening in the direction of an piston inner area, characterized in that one of a widening above and below a bore axis, referenced to a piston stroke axis, is smaller than one of a widening below and above the bore axis.
 2. The piston from claim 1, wherein one of the widening above and below the bore axis, referenced to the piston stroke axis, is smaller in the direction of a piston outer area than one of a widening below and above the bore axis.
 3. The piston from claim 1, wherein the widening in the direction of the piston inner area and in the direction of the piston outer area one of configured trumpet-shaped configuration.
 4. The piston from has a claim 1 wherein surface lines of the piston-pin bore are one of round and oval.
 5. The piston from claim 1, wherein the piston boss is configured as one of a trapezoidal and a stepped boss.
 6. The piston from claim 1 wherein a transition from one section having a first shape to a next section having a different shape of the piston-pin bore is configured continuously.
 7. The piston from claim 6, wherein the one section and the next section have a first section configured circular, a second section configured cylindrical, and a third section configured oval.
 8. The piston from claim 6 wherein the one section and the next section include at least three sections configured as ovals and having different radii of ovality from each other.
 9. The piston from claim 6 wherein starting from a zenith of the piston-pin bore in the direction of the area of the piston facing a combustion chamber and in the direction of the circumference of the piston-pin bore, surface lines are configured elliptically with changing radii over the axial extension and circumference of the piston-pin bore. 